System and method for identifying, reporting, and evaluating presence of substance

ABSTRACT

A system and method for identifying, reporting, and evaluating a presence of a solid, liquid, gas, or other substance of interest, particularly a dangerous, hazardous, or otherwise threatening chemical, biological, or radioactive substance. The system comprises one or more substantially automated, location self-aware remote sensing units; a control unit; and one or more data processing and storage servers. Data is collected by the remote sensing units and transmitted to the control unit; the control unit generates and uploads a report incorporating the data to the servers; and thereafter the report is available for review by a hierarchy of responsive and evaluative authorities via a wide area network. The evaluative authorities include a group of relevant experts who may be widely or even globally distributed.

RELATED APPLICATIONS

The present non-provisional patent application claims, with regard toall common subject matter, priority benefit of a copending provisionalpatent application titled PORTABLE IMAGE RECOGNITION & ANALYSISTRANSDUCERS EQUIPMENT (PIRATE); Ser. No. 60/414,507; filed: Sep. 26,2002. The identified provisional patent application is herebyincorporated by reference into the present non-provisional patentapplication.

FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT PROGRAM

The present invention was developed with support from the U.S.government under Contract No. DE-AC04-01AL66850 with the U.S. Departmentof Energy. Accordingly, the U.S. government has certain rights in thepresent invention.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates broadly to systems and methods fordetecting, identifying, reporting, and evaluating presences ofsubstances. More particularly, the present invention concerns a systemand method for identifying, reporting, and evaluating a presence of asolid, liquid, gas, or other substance of interest, particularly adangerous, hazardous, or otherwise threatening chemical, biological, orradioactive substance. The system comprises one or more substantiallyautomated, location self-aware remote sensing units; a control unit; andone or more data processing and storage servers. Data is collected bythe remote sensing units and transmitted to the control unit; thecontrol unit generates and uploads a report incorporating the data tothe servers; and thereafter the report is available for review by ahierarchy of responsive and evaluative authorities via a wide areanetwork. The evaluative authorities include a group of relevant expertswho may be widely or even globally distributed.

2. Description of the Prior Art

It is often desirable to monitor for, identify, report, and evaluate apresence of a solid, liquid, gaseous, or other substance of interest. Itwill be appreciated, for example, that it has become highly desirable oreven necessary, particularly in light of recent terrorist activities, tomonitor for, identify, report, and evaluate any presence of threateningchemical, biological, or radioactive substances. Many less sinistersubstances, however, are also often the subject of monitoring,including, for example, pollutants; illegal or otherwise regulatedsubstances; substances of interest to science; and substances ofinterest to agriculture or industry.

In the case of threatening substances, for example, detection devicesare well-known in the prior art, ranging from the extremely simple tothe exceedingly complex. Simple detection devices are typically narrowlycapable of detecting and identifying a single substance or group ofclosely related substances. These extremely limited devices typicallycombine detection and identification into a single function by using avery specific test that can only detect the presence or non-presence ofthe specific substance and none other. An expensive and unwieldycollection of these simple devices would be needed in order to monitoror test for the wide variety of substances that might pose threats tohealth and safety. Unfortunately, providing such a collection of deviceson a deployable mobile platform suitable for field testing substanceswhenever and wherever they may be encountered would be difficult andimpractical at best. Furthermore, even if such a large and expensivemobile collection were created, it most likely could not be introducedinto a suspect area in a timely manner and without undue risk to itsoperators. Additionally, unless multiple instances of each device areincluded in the collection, there is no redundancy to amelioratefailure, such as malfunction or mistake, by any particular device.

Furthermore, because these simple devices are often designed forstand-alone operation, integrating their systems, particularly theirdisparate operating and reporting systems, would be an exceedinglydifficult and costly task. Relatedly, even if such integration wereachieved, replacing an older version of a device with a newer versionmight well require substantial additional integration work, therebyproviding a powerful disincentive for upgrading to newer and betterdevices whenever possible. Additionally, being substantially disparateand designed without concern for integration, these simple devices areunable to communicate or cooperate with one another in performing theirrespective functions. Thus, a particular detection device of thecollection may be engaged in substantial and time-consuming testingwhile all other devices sit inefficiently idle.

Prior art complex detection devices are generally more broadly capablethan the above-described simple devices, but they also suffer from anumber of disadvantages. More specifically, increased capability istypically associated with an increase in operational complexity,requiring substantial investments in initial and continued training sothat the complex devices can be used properly and effectively.Furthermore, the devices require substantial operational control by andinteraction with a human operator either in physical contact or closeproximity with the detection device. It will be appreciated that thisnecessarily exposes the operator to the substance being tested, therebyrequiring the operator to wear extremely cumbersome protective gear.This gear, in turn, makes operating any small buttons, dials, or otherinput or control mechanisms on the device extremely difficult.

Relatedly, a lack of any substantial automation of the device means thattesting can only be performed once the necessary human operator arriveson the scene, precluding both continuous monitoring and the fastestpossible identification of the substance. Thus, only once there isreason to suspect that the substance is present (possibly as a result ofanimal or human deaths) might an order be given to deploy the humanoperator and the detection device. Thereafter, the human operator musttravel to the scene and prepare for and perform the appropriate testingwhile wearing cumbersome protective gear and otherwise avoiding exposinghimself or herself to the potentially hazardous substance. Furthermore,though it may be established that the substance is not one of theparticular substances being tested for, actual identification of thesubstance may not be accomplished. During this very inefficient andtime-consuming procedure, a large number of additional people may beexposed to the threatening substance depending on such factors as wind,rain, other weather conditions; insect, animal, or human movements; orother vectors.

Once a positive identification has been made or, at least, the presenceof certain substances has been ruled out, the results observed by theoperator of the device is typically reported to a remote team memberusing short range two-way radios. The remote team member must thentranscribe or enter these reports before they can be relayed to a higherauthority. This inefficient process further delays initiation of anyresponse to the threat, and may introduce communication andtranscription errors.

Additionally, prior art devices typically do not allow for quick andconvenient removal and replacement of malfunctioning or obsoletecomponents. When a malfunction occurs, the device must be taken out ofservice until appropriate maintenance can be performed by a qualifiedtechnician. When improved sensors or other components become available,the entire device must be replaced at substantial cost in order toobtain the benefit of improved performance. Relatedly, the devices aretypically not customizable with regard to performance, capability, orcost.

Additionally, prior art devices typically have no capability to identifyappropriate local, state, or regional contacts for reporting detectionof a threatening substance. Typically, individual detection devices orcollections of such devices are deployed by state or federal agenciesand report only to a particular high-level authority rather than a localauthority (e.g., city or county). Thus, once information has beengathered, it is disseminated, if at all, using a top-down model, whichcan result in substantial delay between initial notification of thestate or federal authorities and notification of the local authoritieswho are charged with responding to the threatening situation, and canresult in substantial confusion if the information is misinterpreted ormiscommunicated as it is repeated up and down this chain. Furthermore,local authorities may have particular protocols or policies in place forsuch reporting that are not available or not followed when notifyingthem of the hazard or threat, thereby further undermining anypossibility of a timely response to the situation.

Due to the above-identified and other problems and disadvantages in theart, a need exists for an improved system and method of identifying,reporting, and evaluating presences of substances, particularlythreatening substances.

SUMMARY OF THE INVENTION

The present invention overcomes the above-described and other problemsand disadvantages encountered in the prior art by providing a system andmethod for identifying, reporting, and evaluating a presence of one ormore solids, liquids, gases, or other substances of interest,particularly dangerous, hazardous, or otherwise threatening chemical,biological, or radioactive substance.

In a preferred embodiment, the system broadly comprises one or moreremote sensing units, hereinafter referred to as “IRAM units” (“ImageRecording and Analysis Methods” units); one or more communications andcontrol units, hereinafter referred to as “OATS units” (“OpenArchitecture Transmission and Supervision” units); a wide areatelecommunications network; and one or more remote data processing andstorage servers. Once the substance of interest is detected, the OATSunit generates and uploads a report detailing its presence and otherrelevant information to the servers, whereafter the report is availablefor review by a hierarchy of response and evaluation authorities via thewide area network.

Each IRAM unit is adapted and operable to substantially automaticallyand independently gather sensor and other data from within an area ofinterest and communicate this data to the OATS unit. Each IRAM unitpreferably includes a position-determining mechanism; a sample collectormechanism; a sample examination cassette; a data collection mechanismfor collecting identifying and other relevant information concerning thesubstance; temperature, wind speed/direction, and rain sensors; atransceiver; a power supply; and a local warning device. The IRAM unituses an open architecture or interface that allows for easily andconveniently removing and replacing the components (so called“plug-and-play”) without having to restart or reboot the IRAM unit(so-called “hot-swapping”), thereby facilitating easy, convenient, andcost-effective removal and replacement of unneeded, malfunctioning, orobsolete components.

The position-determining mechanism automatically and continuallydetermines a particular geographic position or location of the IRAMunit. The sample collection mechanism collects a sample of the substancefrom the environment surrounding the IRAM unit and introduces the sampleto the sample examination cassette. The sample examination cassetteprovides a platform for positioning and otherwise preparing the samplefor investigation by the data collection mechanism, and for subsequentstorage wherein the tested substances and images thereof are preservedfor later removal from the IRAM unit for further testing or storage.

The data collection mechanism is adapted for collecting identifyinginformation concerning the substance, with the information taking anyone or more of a variety of forms, such as, for example, digital images,data points, test results, or sensor results. The data collectionmechanism may include any one or more of the following: an imagingdevice for investigating solids or liquids; a mass spectrometer, gaschromatograph, or ion mobility spectrometer for investigating gases; amultiple reagent and sample treatment module; a radiation sensor;additional desired sensors or detection and identification mechanisms; acontrol module; and a processor and associated memory. Each IRAM unitmay be individually configured as desired, particularly in light of anyrelevant considerations (e.g., needed capabilities, minimized cost). Theaforementioned open architecture facilitates such customization.

The imaging device provides a digital image of the substance forcomparison and analysis to identify solid or liquid substances. Theimaging device may include, for example, a digital microscope; a visualcamera; an infrared camera; or a thermal camera. The mass spectrometer,gas chromatograph, or ion mobility spectrometer provides spectrographicdata points that can be used to identify gaseous substances.

The multiple reagent and sample treatment module allows for performingmicro-chemical or biological testing and analysis of the substance inthe sample examination cassette. More specifically, the sample treatmentmodule allows for testing the substance by treating it with or exposingit to a variety of reagents, growth media, or other chemical orbiological compounds wherein micro-amounts of the compounds areintroduced to a micro-amount or micro-sample of the substance. Use ofthis feature, including introducing the compounds to the substance, maybe remotely controlled by an operator of the OATS unit.

The radiation sensor monitors radiation levels, particularly changes inbackground radiation levels. The additional sensors or detection andidentification mechanisms allow for including more specific testingcapability as necessary or desired, thereby greatly enhancing theoperational flexibility of the system.

The control module provides a mechanism and interface for the operatorof the OATS unit to remotely control operation of the various componentsof the IRAM unit, particularly the imaging device and the sampletreatment module. The processor and associated memory processes andstores data generated by other components of the IRAM unit, andfacilitates communicating this data with the OATS unit. The temperature,wind direction/speed, and rain sensors monitor weather factors that mayimpact effectiveness, movement, and dissipation of many substances andthat are useful in determining whether and how a substance may move orbe moving within a geographic area. The transceiver provides encoded orencrypted two-way communication with the OATS unit. The power supplyprovides power to the other components of the IRAM unit. The localwarning device allows for warning those in relatively close proximity tothe IRAM unit, and therefore to the substance of interest, that apotentially dangerous condition exists.

Each IRAM unit is also preferably provided with a self-rightingmechanism that substantially ensures that the IRAM unit will be properlyoriented following deployment, particularly airborne deployment. Properorientation is especially important to such functions as samplecollection.

The OATS unit is adapted and operable to allow the operator thereof toremotely monitor and, when necessary or desired, control the IRAM units'activities; to perform image analysis on any images received from theIRAM units; and transmit reports on any detected substances of interestto the data processing and storage servers via the wide areatelecommunications network. The OATS unit preferably includes one ormore transceivers; a display; a processor and associated memory; alibrary or database of reference images of known substances; and imageanalysis and recognition software. The OATS unit may also include aposition-determining mechanism.

The one or more transceivers allow for communicating with the IRAM unitsvia a wireless or hardwired local area network and for communicatingwith the data processing and storage servers via the wide areatelecommunications network. Preferably, the OATS unit includes at leasttwo different types of transceiver devices in order to provide greaterflexibility and choice in communications.

The display allows for viewing the data collected and transmitted by theIRAM units. The processor and associated memory control operation ofother components and various functions of the OATS unit, including dataprocessing and storage.

The library or database of reference images of known substances isstored in the memory associated with the processor, or, alternatively,may be accessed in whole or in part from a remote location via thetransceiver. The image analysis and recognition software is stored inthe memory and executed by the processor to compare the image generatedby the imaging device with the reference images in the library. Morespecifically, the image analysis and recognition software compares orotherwise analyzes the generated image of the substance to determinewhich known substance the unidentified substance most resembles basedupon such factors as, for example, color, shape, texture, brightness,color structure, and aspect ratio.

The position-determining mechanism allows the OATS unit to determine itsown geographic position or location, particularly its position relativeto the IRAM units.

The OATS unit preferably has access to a look-up table or other databaseof geographic locations associated with local reporting authorities andlocal reporting protocols or other policies. When data received from anIRAM unit indicates the presence of a threatening substance or othersubstance of interest, the geographic location of the particular IRAMunit, as determined by its onboard position-determining mechanism andtransmitted to the OATS unit along with the collected data, is used inconjunction with the look-up table to identify proper local reportingauthorities and policies. These authorities may, as appropriate, benotified directly to access and review the report stored on the dataprocessing and storage servers.

The OATS units are also preferably adapted and operable to communicateand cooperate with each other and, as desired, with other computingresources in order to engage in or perform distributed or grid computingwherein an otherwise time-consuming processing problem (e.g., imagecomparison in order to identify the substance, or evaluation of multipledata sets from multiple IRAM units) is broken or partitioned intosmaller problems or portions of problems that are processedsubstantially simultaneously and in parallel.

As mentioned, the report setting forth the collected data concerning thesubstance of interest is uploaded to the data processing and storageservers via the wide area network. Thereafter, the report can beaccessed by any authorized person substantially anywhere in the worldvia the wide area network. Each such report preferably includes at leastthe relevant IRAM unit's geographic location coordinates; the time- anddate-stamped digital image or other sensor data associated with thesubstance; and any other relevant information collected by the IRAMunit. The one or more data processing and storage servers may also beadapted to evaluate the data of the report in light of otherconsiderations, including the data of other reports, in order togenerate an overarching picture or perspective involving all availablerelevant data.

The hierarchy of response and evaluation authorities includes responsiveentities and evaluative entities. The responsive entities may include,for example, local first responders; state or regional departments oragencies; and national departments or agencies such as the Department ofHomeland Security or Federal Bureau of Investigation. The evaluativeentities may include, for example, an overarching group of relevantexperts with knowledge of such subjects such as, for example, medicalissues relating to exposure to chemical, biological, or radioactivesubstances; legal, law enforcement, policy, or doctrinal issues; andhistorical cases, modeling, or simulation. Because the report isuploaded to the data processing and data storage servers and isthereafter accessible via the wide area network, the group of relevantexperts may include substantially any experts or other appropriatepersons located anywhere in the world. Advantageously, this allows forinvolving the most knowledgeable or otherwise best-choice expertswithout regard to their locations.

Thus, it will be appreciated that the system and method of the presentinvention provide a number of substantial advantages over the prior art,including, for example, providing a substantially automated and remotelycontrollable remote sensing unit that both allows for faster deploymentand eliminates exposure risks to human operators. More specifically, theIRAM units can be temporarily deployed in any suitable manner (e.g.,airdrop, balloon, robot) into an area to provide the quickest warning ofthe presence of a threatening substance. The IRAM units can also bepermanently deployed, for example, in a single layer or concentriclayers around a city to provide continuous monitoring and advancewarning of a terrorist attack using weapons of mass destruction or otherthreatening substances. Such operational flexibility is not possible inthe prior art, in part because a human operator must be outfitted anddeployed with the prior art detection devices and because the prior artmethods of testing and reporting are inefficient and time-consuming.

Furthermore, the open architecture of the IRAM unit allows for easy andconvenient removal and replacement of malfunctioning or obsoletesensors, thereby reducing maintenance time and making the system moreresistant to obsolescence. The open architecture also allows for anunprecedented degree of customizability to meet cost, capability,anticipated need, and other considerations.

Additionally, when the IRAM unit is equipped with the imaging device,the broadly capable image analysis and recognition technique of thepresent invention advantageously allows for more efficient, practical,and cost-effective monitoring and reporting than is possible with thesubstance-specific or interaction-intensive techniques used by the priorart.

Additionally, the feature of location self-awareness allows for fasternotification of appropriate local authorities, and the feature of gridcomputing allows for cooperative processing resulting in much fasteridentification, evaluation, and response to potentially dangerous ordeadly situations.

Additionally, the two or more types of transceivers on each OATS unitallow for greater communication flexibility and options during anemergency. More specifically, the preferred primary transceiver is usedwhenever possible and a secondary transceiver is used whenevernecessary.

Additionally, by uploading reports describing the presence of asubstance of interest into the one or more data processing and storageservers and establishing authorized access to the reports via the widearea network, the present invention makes possible the introduction andcontribution of the group of relevant experts even though the group'smembers may be widely or even globally distributed.

These and other important features of the present invention are morefully described in the section titled DETAILED DESCRIPTION OF APREFERRED EMBODIMENT, below.

BRIEF DESCRIPTION OF THE DRAWINGS

A preferred embodiment of the present invention is described in detailbelow with reference to the attached drawing figures, wherein:

FIG. 1 is a block diagram of a system 10 for identifying, reporting, andevaluating a presence of a dangerous, hazardous or otherwise threateningsolid, liquid, gas, or other substance, implemented in accordance with apreferred embodiment of the present invention;

FIG. 2 is a block diagram showing elements of multiple IRAM units 12 andan OATS unit 14 which are components of the system 10 of FIG. 1;

FIG. 3 is a block diagram showing the interrelation of elements of asample examination cassette 28 which is a component of the system 10 ofFIG. 1;

FIG. 3A is a block diagram showing the interrelation of elements of analternative embodiment of the sample examination cassette 128 which is acomponent of the system 10 of FIG. 1;

FIG. 4 is a depiction of a self-righting mechanism 62 which is acomponent of the IRAM unit 12 of the system 10 of FIG. 1;

FIG. 5 is a first portion of a flowchart of steps involved in practicingthe present invention;

FIG. 6 is a second portion of the flowchart beginning in FIG. 5;

FIG. 7 is a third portion of the flowchart beginning in FIG. 5; and

FIG. 8 is a block diagram showing elements in an alternativeimplementation of the IRAM unit 112 and OATS unit 114 of the system 10of FIG. 1.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT

With reference to the figures, a system 10 and method is hereindescribed, shown, and otherwise disclosed in accordance with a preferredembodiment of the present invention. Broadly, the present inventionconcerns a system 10 and method for identifying, reporting, andevaluating a presence of one or more solids, liquids, gases, or othersubstances of interest, particularly dangerous, hazardous, or otherwisethreatening chemical, biological, or radioactive substances.

System

Referring particularly to FIGS. 1 and 2, the system 10 broadly comprisesone or more IRAM units 12; one or more OATS units 14; a wide areatelecommunications network 16; and one or more remote data processingand storage servers 18. As discussed below, once the substance ofinterest is detected, the OATS unit 14 generates and uploads a reportdetailing its presence and other relevant information to the servers 18,whereafter the report is available for review by a hierarchy of responseand evaluation authorities 20 via the wide area network 16.

Each IRAM unit 12 is adapted to substantially automatically andindependently gather sensor and other data from within an area ofinterest 22 and communicate this data to the OATS unit 14. Each IRAMunit 12 preferably includes a position-determining mechanism 24; asample collector mechanism 26; a sample examination cassette 28; a datacollection mechanism 30 for collecting identifying and other relevantinformation concerning the substance; temperature, wind speed/direction,and rain sensors 32; a transceiver 34; a power supply 36; and a localwarning device 38. The data collection mechanism 30 may include any oneor more of the following: an imaging device 40 for investigating solidsor liquids; a mass spectrometer 42, gas chromatograph, or ion mobilityspectrometer for investigating gases; a multiple reagent and sampletreatment module 44; a radiation sensor 46; additional relevant sensorsor detection and identification mechanisms 48; a control module 50; anda processor 52 and associated memory. Substantially all of theaforementioned IRAM unit components are conventional, commonly availableoff-the-shelf devices. The IRAM unit 12 preferably uses an openarchitecture or interface from the IEEE 1451 family of intelligentsensor interfaces or an equivalent that allows for easily andconveniently removing and replacing the components (so called“plug-and-play”) without having to restart or reboot the IRAM unit 12(so-called “hot-swapping”), thereby facilitating easy, convenient, andcost-effective removal and replacement of unneeded, malfunctioning, orobsolete components.

The position-determining mechanism 24 is preferably a global positioningsystem (GPS) receiver adapted to receive signals from a plurality oforbiting satellites and, based thereon, automatically and continuallydetermine a particular geographic position or location of the IRAM unit12. A suitable GPS receiver is available, for example, as the modelGPS16 from Garmin International, Inc., which provides 12 satellitetriangulation, WAAS capability, 3 meter accuracy, and an RS232 output.It will be appreciated that under some circumstances and in certainapplications it is desirable to know the IRAM unit's position in greaterdetail, possibly including, for example, its directional orientation.Thus, the position-determining mechanism 24 may be adapted to providesuch additional detail.

The sample collection mechanism 26 collects a sample of the substancefrom the environment 22 surrounding the IRAM unit 12. The collectionmechanism 26 may include an extendable arm-type collection component forcollecting samples of solids, a pump-based suction-type collectioncomponent for collecting samples of liquid or gaseous substances, anycombination thereof, or any other desired collection component using anysuitable collection technique. The collected sample is introduced to thesample examination cassette 28.

Referring also to FIG. 3, the sample examination cassette 28 provides aplatform for positioning and otherwise preparing the sample of thesubstance for investigation by the data collection mechanism 30, and forsubsequent storage. The cassette 28 includes a roll of filter paper 56and an archive spool 58. Where the data collection mechanism 30 includesthe imaging device 40 (described below), the cassette will alsopreferably include a roll of film 60 or other medium providing animpermeable barrier for separating and isolating the various samples ofsubstances. The roll of filter paper 56 is a roll of sample collectionand reagent HEPA filter paper media mounted on a first spool and ontowhich the sample collection mechanism 26 deposits the sample. The rollof film 60 is mounted on a second spool and covers the filter paper asit is wound upon the archive spool 58. The archive spool 58 collects andstores the advancing rolls of filter paper 56 and film 60 so that thetested substances are preserved for later removal from the IRAM unit 12and further testing or storage.

Referring also to FIG. 3A, an alternative embodiment of the sampleexamination cassette 128 is shown including a movable stage 156; a sheetof the filter paper 157; and a superimposed grid 158. The sheet offilter paper 157 is placed upon the movable stage 156 and a vacuum usedto hold it in place, then the grid 158 is superimposed upon the filterpaper 157 so as to define a plurality of sample areas 159 and a reservedarea 160. In use, the stage 156 moves (by, e.g., stepper motors)relative to the sample collection mechanism 26 so that the sample isintroduced to or deposited within a particular sample area defined bythe grid 158. No sample is ever introduced to the reserved area 160because that location corresponds to the sample treatment module 44. Thestage 156 then moves so as to position the particular sample area andthe substance located therein before the imaging device 40 or, iftesting is desired, before the sample treatment module 44. This processis repeated for each sample of each substance until the plurality ofsample areas 159 are full. Thereafter, the sheet of filter paper 157 maybe removed for further testing or storage. It will be appreciated thatthis alternative embodiment eliminates the roll of film 60 and thearchive spool 58 of the previously-described embodiment.

The data collection mechanism 30 is adapted for collecting identifyinginformation concerning the substance. This information may take any oneor more of a variety of forms, including, for example, digital images,data points, test results, or sensor results. As mentioned, the datacollection mechanism 30 may include any one or more of the following: animaging device 40 for investigating solids or liquids; a massspectrometer 42, gas chromatograph, or ion mobility spectrometer forinvestigating gases; a multiple reagent and sample treatment module 44;a radiation sensor 46; additional desired sensors or detection andidentification mechanisms 48; a control module 50; and a processor 52and associated memory. As shown in FIG. 2, each IRAM unit 12 may beindividually configured as desired, particularly in light of anyrelevant considerations (e.g., needed capabilities, minimized cost). Forexample, a first IRAM unit 12 a is shown equipped with the imagingdevice 40, the sample treatment module 44, and the radiation sensor 46;a second IRAM unit 12 b is shown equipped with the mass spectrometer 42;and a third IRAM unit 12 c is shown equipped with other desired sensors48. The aforementioned open architecture facilitates such customization.

The imaging device 40 provides a digital image of the substance forcomparison and analysis to identify solid or liquid substances. Theimaging device 40 may include a digital microscope adapted to providehighly-magnified LIVE images and SNAP capture capabilities and to outputin a tif or other standard format. A suitable digital microscope isavailable, for example, as the model VL-S from Scalar Corporation, whichprovides 1× to 400× magnification, color images, and S-video output.

Alternatively, the imaging device 40 may include any of a variety ofimage capturing cameras, such as, for example, visual cameras; infraredcameras; or thermal cameras, all of which generate images that can beanalyzed using the image analysis and recognition techniques discussedbelow. It will be appreciated that these image capturing cameras aremore suited for identifying objects or persons than biological,chemical, or radioactive substances. It is contemplated that the presentinvention can also be used to remotely locate or identify objects orpersons. For example, the IRAM unit 12 could be made mobile and used byfirefighters to investigate burning or smoke filled areas for trappedpersons. In another example, the IRAM unit 12 could be deployed about anevent or location to identify terrorists, criminals, or other personsusing facial recognition or other identification techniques.

The mass spectrometer 42, gas chromatograph, or ion mobilityspectrometer provides spectrographic data points that can be used toidentify gaseous substances. A suitable ion mobility spectrometer isavailable, for example, as the model APD2000 from Smiths Detection,which is operable to detect such chemical substances as, for example,GA, GB, GD, VX, HD, HN, lewisite, pepper spray, and mace. Alternatively,the mass spectrometer 42 or other similar device may provide a digitalimage of the spectrograph of the substance for comparison analysis in amanner similar to the digital image generated by the imaging device 40described above.

The multiple reagent and sample treatment module 44 allows forperforming micro-chemical or biological testing and analysis of thesubstance in the sample examination cassette 28. More specifically, thesample treatment module 44 allows for testing the substance by treatingit with or exposing it to a variety of reagents, growth media, or otherchemical or biological compounds wherein micro-amounts of the compoundsare introduced to a micro-amount or micro-sample of the substance. Ifthe IRAM unit 12 is also equipped with the aforementioned imaging device40, then this process of testing and analysis and any results thereofmay be viewable in real-time. Preferably, a number of suchmicro-chemical or biological tests are performed substantiallysimultaneously, with micro-amounts of multiple compounds beingsimultaneously introduced to multiple micro-samples of the substance,wherein the imaging device 40 moves over the samples or the samples moverelative the imaging device 40 in order to provide images of each of thesimultaneously-occurring tests. Use of this feature, includingintroducing the compounds to the substance, may be remotely controlledby an operator of the OATS unit 14.

The radiation sensor 46 monitors radiation levels, particularly changesin background radiation levels. A suitable radiation monitor isavailable, for example, as the model RAM R200 from Rotem Industries,Inc., which measures between 10 μR/h and 100 R/hour and provides anRS232 output.

The additional sensors or detection and identification mechanisms 48allow for including more specific testing capability as necessary ordesired. This capability may be stand-alone as in the third IRAM unit 12c, or may, for example, be used to supplement the images generated bythe imaging device 40. The additional sensors or mechanisms 48 mayinclude, for example, GC/MS sensors, chemical sensors, biologicalsensors, acoustic sensors, visual sensors, movement sensors, seismicsensors, magnetic sensors, or solar sensors.

The control module 50 provides a mechanism and interface for theoperator of the OATS unit 14 to remotely control operation of thevarious components of the IRAM unit 12, particularly the imaging device40 and the sample treatment module 44. The capabilities of the controlmodule 50 will depend heavily on the nature and capabilities of thecomponents being controlled. In the case of a digital microscopes forexample, the control module 50 may allow the operator to adjustmagnification, field of view, and focus using one or more steppermotors. A suitable control module is available, for example, as themodel PCI/2-8x1 switch module from Cytec Corporation, which providesDB-37 pin output.

The processor 52 and associated memory processes and stores datagenerated by the other components of the IRAM unit 12, and facilitatescommunicating this data with the OATS unit 14. The processor 52 may useany suitable operating system, such as, for example, the Windows 98SEoperating system available from Microsoft Corp., and may be providedwith a USB/RS232 converter for interfacing or facilitating communicationwith other components of the IRAM unit 12. A suitable converter thatprovides up to four channels for sensors is available, for example, asthe model USB232/4 from National Instruments. The processor 52 is alsoadapted and operable to perform various other necessary onboardoperating functions, including, for example, calibrating, integrating,and otherwise managing the various sensors, transducers, and othercomponents, and collecting samples using the sample collection mechanism26.

The temperature, wind direction/speed, and rain sensors 32 monitorpotentially relevant weather factors that may impact effectiveness,movement, or dissipation of many substances and that are useful indetermining whether and how a substance may move or be moving within ageographic area. High or low temperatures, for example, may deactivatecertain threatening chemicals; winds may spread or dissipate threateninggases; rain may dilute or destroy threatening powders or introducethreatening liquids into water supplies. A suitable weather station isavailable, for example, from Texas Weather Instruments, Inc., whichprovides temperature, wind direction/speed, and rain sensingcapabilities and a DDE-link output.

The transceiver 34 provides encoded or encrypted two-way communicationwith the OATS unit 14. Data collected by the data collection mechanism30, for example, is transferred as simple batch files using SecureSocket Layer (SSL) with 1024 bit encryption. Control signals from theOATS unit 14 to the control module 50 or processor 52 are alsocommunicated in this manner. As desired, each IRAM Unit 12 may includemore than one transceiver, type of transceiver, or type ofcommunications mode in order to provide greater flexibility and choicein communications. The transceiver device 34 preferably makes use of awireless LAN Ethernet link using any appropriate IEEE 802-familystandard. A suitable wireless Ethernet link may be implemented using,for example, the model BEFW11S4 router from Linksys, providing fourchannel access points and 2.4 GHz using the IEEE 802.11b standard.Unfortunately, wireless communication is not always practical, may bejammed, or be otherwise unusable (e.g., due to interference). Forexample, the IRAM unit 12 may be deployed into an artificial structure,underground, or other area where wireless communications are naturallyor artificially inhibited. Thus, provision is preferably made forattaching a communications cable (e.g., Ethernet cable connection) tothe IRAM unit 12 to allow for a hardwired LAN Ethernet link whennecessary or desirable.

The power supply 36 provides power to the other components of the IRAMunit 12. A suitable power supply is available, for example, as the modelLPQ-112 power supply from Astec Power. It is also contemplated that thepower supply 36 could be a hydrogen fuel cell or variation thereof.Furthermore, where the IRAM unit's location is fixed, such as whenpermanently positioned around or within a city, the primary power supply36 may be a hardwired connection to a reliable, permanent power supply,possibly supplemented or backed-up by a battery, hydrogen fuel cell, orother secondary self-contained power supply.

The local warning device 38 allows for warning those in relatively closeproximity to the IRAM unit 12, and therefore to the substance ofinterest, that a potentially dangerous condition exists. The localwarning device 38 can be activated by any onboard sensor or detectiondevice able to make a positive identification of the substance (e.g.,the radiation sensor 46 or other specialized sensor or detector 48). Thelocal warning device 38 may take the form of any device, such as, forexample, a horn, siren, or flashing light, adapted and operable toprovide a significant audible or visual warning.

Preferably, at least any sensitive component or portion of the IRAM unit12 is substantially surrounded with a protective potting or hardeningmaterial 39. The nature of the material 39 will depend upon the natureof the sensitivity. For example, an impact-sensitive component may besubstantially surrounded by a cushioning expandable foam or bycushioning micro-capsules; a temperature-sensitive component may besubstantially surrounded by an insulative material; and atamper-sensitive component may be substantially surrounded by a materialthat inhibits or prevents physical or other access to the component.

Self-righting Mechanism

Referring also to FIG. 4, each IRAM unit 12 is preferably provided witha self-righting mechanism 62 that substantially ensures that the IRAMunit 12 will be properly oriented following deployment, particularlyairborne deployment. Proper orientation may be especially important tosuch functions as sample collection. One possible self-rightingmechanism 62 involves giving the IRAM unit 12 a substantially sphericalform and offsetting its center of gravity 64 appropriately apart fromone or more inlet and outlet ports associated with the sample collectionmechanism 26. If the IRAM unit 12 lands or otherwise finds itself in animproper orientation, the spherical shape causes the IRAM unit 12 toroll until the center of gravity 64 is located as low as possible,thereby orienting the IRAM unit 12 so as to properly position its intakeand exhaust ports for operation. The spherical shape may be a fixedfeature or, alternatively, may be the result of an inflatable balloon 66or balloon-like structure that, when deflated, allows for storing theIRAM unit 12 in a more efficient rectangular shape prior to deployment,and, when inflated, allows for assuming the self-righting sphericalshape during or after deployment.

Oats Unit

The OATS unit 14 is adapted and operable to allow the operator thereofto remotely monitor and, when necessary or desired, control the IRAMunits' activities; to perform image analysis on any images received fromthe IRAM units 12; and transmit reports on any detected substances ofinterest to the data processing and storage servers 18 via the wide areatelecommunications network 16.

The OATS unit 14 preferably includes one or more transceivers 70; adisplay 72; a processor 74 and associated memory; a library 76 ordatabase of reference images of known substances; and image analysis andrecognition software 78. The OATS unit 14 may also include aposition-determining mechanism 80.

The one or more transceivers 56 allow for communicating with the IRAMunits 12 via a wireless or hardwired local area network and forcommunicating with the data processing and storage servers 18 via thewide area telecommunications network 16. Preferably, the OATS unit 14includes at least two different types of transceiver devices in order toprovide greater flexibility and choice in communications. A primarytransceiver device 70 a may, for example, be adapted for wirelesscellular telephone communication that allows for relatively inexpensive,omnidirectional, and high-bandwidth communication. Unfortunately, suchwireless services are not available everywhere or may exceed capacityand jam or be otherwise unusable (e.g., due to interference) during anemergency. Thus, a secondary transceiver device 70 b may, for example,be a satellite phone link that is more widely available and usableduring an emergency.

In more detail, the OATS unit 14 communicates with the IRAM units 12using wireless DHCP LAN addressing and encryption; while the OATS unit14 uploads data to the data processing and storage servers 18 andcommunicates with external parties and agencies using TCP/IP WANdomains, addressing, SSL (128 bit minimum) encoding, and digitalcertificates. As desired, other suitable data scrambling schemes may beused, such as, for example, SSH or WEP. Encoding may be sufficient forcommunicating information that is unclassified but sensitive; encryptionmay be used where greater security is required or desired. The wide areanetwork may be, for example, the Internet, which is particularlysuitable for civilian use, or a more secure, limited access network,which is more suitable for military or other government use.

The display 72 allows for viewing the data collected and transmitted bythe IRAM units 12. The OATS unit 14 preferably provides a LabVIEW-basedor similar user interface for display on the display 72 and adapted tocommunicate the received data to the operator of the OATS unit 14 and tofacilitate monitoring and controlling the IRAM unit's various functions,including, for example, controlling pan, zoom, and other functions ofthe imaging device 40; monitoring and controlling activities of thesample treatment module 44; viewing the location coordinates of the IRAMunit 12 as generated by the IRAM unit's position determining mechanism24; and viewing the digital image or other data generated or collectedby the data collection mechanism 30 and various other sensors ordetectors. The user interface also preferably provides for initiating orviewing results of system diagnostics to ensure and maintain adequatesensing and control. The user interface also preferably facilitatesuploading reports to the data processing and storage servers 18 forstorage and subsequent review via the wide area network 16 by anyauthorized person substantially anywhere in the world.

The processor 74 and associated memory control operation of othercomponents and various functions of the OATS unit 14, including dataprocessing and storage. The processor 74 may be provided with anysuitable operating system, such as, for example, the Linux version 7.0operating system available from Red Hat, Inc., or the Windows 2000operating system available from Microsoft Corp.

The library 76 or database of reference images of known substances isstored in the memory associated with the processor 74 or, alternatively,may be accessed in whole or in part from a remote location via thetransceiver 70. The image analysis and recognition software 78 is storedin the memory and executed by the processor 74 to compare the imagegenerated by the imaging device 40 with the reference images in thelibrary 76. More specifically, the image analysis and recognitionsoftware 78 is adapted to access the reference images and compare orotherwise analyze the generated image of the substance to determinewhich known substance the unidentified substance most resembles. Theimage analysis and recognition software 78 compares the generated imagewith the reference images based upon such factors as, for example,color, shape, texture, brightness, color structure, and aspect ratio. Itis possible that no exact match will be made, and instead a number ofreference images will be identified as closely matching the generatedimage. Preferably, the reference images are provided with a threatindicator to quickly communicate their threat potential. In oneimplementation, for example, the threat indicator takes the form of ared, yellow, or green border surrounding each reference image, whereinred indicates a hazardous substance or high threat, yellow indicates aquestionable substance or possible threat, and green indicates low or nothreat, thereby allowing for quick determination of the threat levelposed by a particular substance. The image analysis and recognitionsoftware 78 may, as desired, be calibrated periodically using one ormore calibration/standardization images of known substances which mayalso be stored in the library 76.

As mentioned, the present invention can also be adapted to identify orlocate objects or persons. Thus, the preferred image analysis andrecognition software 78 is broadly capable of identifying substances,objects, and persons, as desired, given the image generated by the IRAMunit 12. For example, the image analysis and recognition software 78 ispreferably capable of or adaptable so as to be capable of recognizingfacial or other bodily characteristics, thereby allowing for identifyingpersons of interest.

The position-determining mechanism 82 allows the OATS unit 14 todetermine its own geographic position or location, particularly itsposition relative to the IRAM units 12.

Location Self-awareness Feature

The OATS unit 14 preferably has access to a look-up table 82 or otherdatabase of geographic locations associated with local reportingauthorities (e.g., police departments, sheriff departments, firedepartments, elected officials, other first responders) and localreporting protocols or other policies. The look-up table 82 may bestored on the memory associated with the processor 74 or may be accessedfrom a remote location via the transceiver 70.

When data received from an IRAM unit 12 indicates the presence of athreatening substance or other substance of interest, the geographiclocation of the particular IRAM unit 12, as determined by its onboardposition-determining mechanism 24 and transmitted to the OATS unit 14along with the collected data, is used in conjunction with the look-uptable 82 to identify proper local reporting authorities and reportingprotocols and other policies. These authorities may, as appropriate, benotified directly (e.g., via electronic mail, telephone, or pager) toaccess and review the report stored on the data processing and storageservers 18 via the wide area network 16.

Thus, prior art failings with regard to both timely dissemination ofcorrect information and compliance with local reporting protocols andother policies are advantageously overcome.

Grid Computing Feature

The OATS units 14 are preferably adapted and operable to communicate andcooperate with each other and, as desired, with other computingresources in order to engage in or perform distributed or grid computingwherein an otherwise time-consuming processing problem (e.g., imagecomparison in order to identify the substance) is broken or partitionedinto smaller problems or portions of problems that are processedsubstantially simultaneously and in parallel. The results of theprocessing of these smaller problems or portions of problems aresubsequently combined or otherwise integrated to arrive at a result forthe larger, more complex problem. Though the broad concept of gridcomputing is known in the prior art, and appropriate software exists orcan be readily generated by one with ordinary skill in the art ofcomputer programming, the use of grid computing is unknown in thefield-testing equipment to which the present invention relates.

Additionally or alternatively, the IRAM units 12 may engage in orperform grid computing. It should be noted that, preferably, the IRAMunits 12 do not communicate directly with one another. Instead, suchcommunication is facilitated by and only occurs through the OATS unit14. Alternatively, the system 10 may be implemented to allow the IRAMunits 12 to communicate independent of the OATS unit 14, particularlywhen communicating about such matters as grid computing.

Servers

As mentioned, the report setting forth collected data concerning thesubstance of interest is uploaded to the data processing and storageservers 18 via the wide area network 16. Thereafter, the report can beaccessed by any authorized person substantially anywhere in the worldvia the wide area network 16. Each such report preferably includes atleast the reporting IRAM unit's geographic location coordinates; thetime- and date-stamped digital image or other sensor data associatedwith the tested substance; and any other relevant information collectedby the IRAM unit 12.

The one or more data processing and storage servers 18 may be providedwith and employ artificial intelligence or similar logic or otherevaluative software 84 to evaluate the data of the report in light ofother considerations, including the data of other reports. In thismanner, though each OATS unit 14 knows only of the data collected by itsown IRAM units 12, an overarching picture or perspective involving allavailable relevant data can be created and evaluated. Such large scaleevaluation may, for example, involve plume or other downwind hazardprediction software models or vector software models or simulations. Thedata processing and storage servers 18 may engage in or perform gridcomputing (in the manner described above) in order to more quickly andefficiently conduct the aforementioned large scale evaluation.

The data processing and storage servers 18 are preferably mirrored toassure data security and reliability.

System Access Management Scheme

It will be appreciated that electronic mail and similar communicationmechanisms suffer from a number of disadvantages that make themunsuitable for use in disseminating or making available the reportsgenerated by the present invention. More specifically, electronic mailtechnologies are point-to-point in nature with no managed, permanent,and shared repository of enterprise-wide program knowledge. There islittle or no security, and “need-to-know” control is managed informallyby each user. Furthermore, electronic mail technologies typically cannotexchange or cannot efficiently exchange large (10 Mbytes or greater)attachments.

Thus, the data processing and storage servers 18 preferably provide anetwork-based multi-point repository service having an adequate controlenvironment to ensure that need-to-know control is properly managed,even for unclassified non-sensitive information pools. This file-sharingsystem should support administration and information managementfunctions such as, for example, back-up recovery; audit trails; and fullinteroperation with standard enterprise desktop and operatingenvironments with little or no software installation, maintenance, orcosts required. The file-sharing system should also include a searchableand administrated meta-data structure to allow users to navigate theenterprise's shared and growing information pool. Additionally, thefile-sharing system should support existing standard electronic mail andweb browser technology without requiring any software modules, plugins,or other modifications to the users' equipment.

Preferably, a user interface in the form of a website hosted by the dataprocessing and storage servers 18 is developed that both supports aprocess whereby new users can gain initial access to and existing userscan navigate through the stored reports.

Gaining initial access to the file-sharing system and the reports storedtherein preferably involves a voucher mechanism whereby an existing useror other authorized person (e.g., project supervisor) is contacted andcommunicated with directly (not via, e.g., electronic or voice mail) tovouch for the new user requesting initial access. The vouching personalso indicates the types of information that the new user has a need toknow. One or more initial passwords will be provided to the new user,preferably by a secure communication medium, but the initial passwordsmust be changed once the user has successfully used them to access thewebsite for the first time. Furthermore, it may be required that thepasswords be changed periodically. Separate directories may be providedfor each level of the hierarchy of authorities (e.g., local, state,regional, national) to facilitate efficient navigation.

As mentioned, when a report is uploaded, appropriate members of thehierarchy of authorities may be notified using any practical mechanismof the need to login to the data processing and storage servers 18 andview the particular report.

Hierarchy of Response and Evaluation Authorities

As mentioned, the present invention contemplates a hierarchy of responseand evaluation authorities 20, including responsive entities 20 a andevaluative entities 20 b. The responsive entities 20 a may include, forexample, such as local (e.g., city or county) first responders (e.g.,police, firefighters, emergency medical services); state or regionaldepartments or agencies; national departments or agencies such as theDepartment of Homeland Security or Federal Bureau of Investigation. Theevaluative entities 20 b may include, for example, an overarching groupof relevant experts on subjects such as, for example, medical issuesrelating to exposure to chemical, biological, or radioactive substances;legal, law enforcement, policy, or doctrinal issues; and historicalcases, modeling, or simulation.

Also as mentioned, the location self-awareness feature of the IRAM units12 and OATS unit 14 allows for associating GPS-determined geographiclocations of substances of interest with specific contact informationand specific policies and protocols for appropriate local authorities.Thus, for example, city A may require that a particular HAZMAT responderor team of HAZMAT responders be notified first of any detection ofhazardous substances, while county B may require that the countysheriff's office and county health department both be notified first.Given the above-described look-up table 82, the OATS unit 14 need onlyreceive and look-up the geographic location of the detecting IRAM unit12 to match the location to the proper authority and policy, andimplement the policy by notifying the appropriate authorities of thedetection and request that they access the one or more processing anddata storage servers 18 to view the full report. A default policy may beprovided for authorities who have no specific requirements.

Because the report is uploaded to the data processing and data storageservers 18 and is thereafter accessible via the wide area network 16,the group of relevant experts 20 b may include substantially any expertsor other appropriate persons located anywhere in the world.Advantageously, this allows for involving the most knowledgeable orotherwise best-choice experts without regard to their locations. Theexperts have full access to the report data, including the imagegenerated by the imaging device 40, any results generated by the sampletreatment module 44, and other sensor data.

EXAMPLE

It will be appreciated that the system 10 of the present invention maybe adapted for use in any number of applications, such as, for example,monitoring hazardous industrial pollutants; monitoring agricultural ormanufacturing areas for beneficial or harmful substances; detecting actsof terrorism involving nuclear, biological, or chemical weapons;monitoring battlefields or other hostile areas; or monitoring suspect orsensitive areas for intelligence gathering purposes.

In an illustrative example of use and operation, the system 10 of thepresent invention may function as follows. Referring particularly toFIGS. 5-7, in response to a spill or leak of hazardous or threateningsubstances, multiple IRAM units 12 are prepared to be airdropped intothe surrounding area to confirm the presence of the substances andextent of contamination. In the process of this deployment, a neededsensor in one of the IRAM units 12 is diagnosed as faulty. The faultysensor is removed and a replacement installed in seconds, as depicted inbox 100, thanks to the IRAM unit's open architecture and ability to “hotswap” sensors without rebooting. Similarly, an operational but obsoletesensor is equally easily removed and replaced, as depicted in box 102.In order to ensure the most up-to-date information, the library 76 ofreference images is updated by downloading the latest reference imagesof known substances, as depicted in box 104.

Upon being airdropped and hitting the ground, the self-rightingmechanism 62 activates or otherwise acts to properly orient each IRAMunit 12, as depicted in box 106. The sample collection mechanism 26collects a sample of a substance to be identified and deposits it ontothe roll of filter paper 46 within the sample examination cassette 28,as depicted in box 108. The sample treatment module 44 automatically orunder direction of the operator of the OATS unit 14 introduces anyreagents, growth media, or other compounds or otherwise performs anydesired chemical or biological testing on the sample, as depicted in box110. The imaging device 40 then generates a digital image of the suspectsolid or liquid, as depicted in box 112. This image is transmitted tothe OATS unit 14 where the image analysis and recognition software 78compares or otherwise analyzes the image against the library 76 ofreference images, as depicted in box 114.

If the image of the substance does not exactly match any particularreference image in the library 76, but does match, within apre-established margin of error, a number of reference images, the OATSunit 14 may arrange the closest matching reference images from best toworst and present these to the operator of the OATS unit 14 or otherauthority for further analysis. Alternatively or additionally, the imageanalysis and recognition software 78 may allow for assigning aprobability or determining a degree to which the generated digital imageof the substance matches the one or more closest reference images, andreporting such.

Once the substance is identified, the filter paper 56 on which thetested sample of the substance resides and the roll of film 60 providingan impermeable barrier for isolating the substance are rolled onto thearchive spool 58 for later removal and possible further analysis orstorage, as depicted in box 116. The temperature, wind direction/speed,and rain sensors 32 provide weather information relevant to movement ordispersal of or otherwise affecting any threatening substance, asdepicted in box 118. The radiation sensor 46 detects any change inbackground radiation, as depicted in box 120. This information istransmitted to the OATS unit 14.

The OATS unit 14 then generates a report incorporating all of thisinformation, as depicted in box 122. The report may include thegenerated image of the substance and the matching or closely matchingreference image(s); the IRAM unit's geographic location as determined bythe onboard position determining mechanism 24; a probability reflectingthe degree of confidence that the match is correct such that thesubstance has been correctly identified; and all other sensor data.

If the generated image of the substance matches a reference image of athreatening substance, then the OATS unit processor 74 accesses thelook-up table 82 of local authorities and policies or protocols. Anappropriate local authority and policy or protocol is identified fromthe look-up table 82 based upon the detecting IRAM unit's geographiclocation, as depicted in box 124. If no particular authority or policyor protocol is specified for the particular location, a default is used.Policy and protocol information may include when or under whatcircumstances to report; whom to report to; and in what form or how toreport. If appropriate, the local authority is notified to access andreview the report. The primary transceiver 70 a of the OATS unit 14communicates and uploads the report to the data processing and storageservers 18, as depicted in box 126. All such communication isappropriately encoded.

The one or more data processing and storage servers 18 may gather thereport, other reports from other OATS units 14, and other relevant data,and input this information into appropriate artificial intelligence orother software tools to provide a broad evaluative overview orperspective of the situation, as depicted in box 128.

Depending on the nature of the identified substance, the particularcircumstances surrounding its presence, and established protocols,appropriate authorities may be notified to access the one or more dataprocessing and storage servers 18 in order to review the report, asdepicted in box 130. Such notification may be accomplished using anyconventional mechanism.

An agency in the hierarchy of response and evaluation authorities 20requests that particular, relevant experts from the group of expertsreview the report and provide additional evaluation and insight, asdepicted in box 132. The particular experts are widely distributedacross the globe, but are able to quickly access and review the reportvia the Internet 16.

Advantages

From the preceding description it will be appreciated that the systemand method of the present invention provide a number of substantialadvantages over the prior art, including, for example, providing asubstantially automated and remotely controllable remote sensing unitthat both allows for faster deployment and eliminates exposure risks tohuman operators. More specifically, the IRAM units can be temporarilydeployed in any suitable manner (e.g., airdrop, balloon, robot) into anarea to provide the quickest warning of the presence of a threateningsubstance. The IRAM units can also be permanently deployed, for example,in a single layer or concentric layers around a city to providecontinuous monitoring and advance warning of a terrorist attack usingweapons of mass destruction or other threatening substances. Suchoperational flexibility is not possible in the prior art, in partbecause a human operator must be outfitted and deployed with the testingequipment and because the prior art methods of testing and reporting areinefficient and time-consuming.

Furthermore, the open architecture of the IRAM unit allows for easy andconvenient removal and replacement of malfunctioning or obsoletesensors, thereby reducing maintenance time and making the system moreresistant to obsolescence. The open architecture also allows for anunprecedented degree of customizability to meet cost, capability,anticipated need, and other considerations.

Additionally, when the IRAM unit is equipped with the imaging device,the broadly capable image analysis and recognition technique of thepresent invention advantageously allows for more efficient, practical,and cost-effective monitoring and reporting than is possible with thesubstance-specific or interaction-intensive techniques used by the priorart.

Additionally, the feature of location self-awareness allows for fasternotification of appropriate local authorities, and the feature of gridcomputing allows for cooperative processing resulting in much fasteridentification, evaluation, and response to potentially dangerous ordeadly situations.

Additionally, the two or more types of transceivers on each OATS unitallow for greater communication flexibility and options during anemergency. More specifically, the preferred primary transceiver is usedwhenever possible and a secondary transceiver is used whenevernecessary.

Additionally, by uploading reports describing the presence of asubstance of interest into the one or more data processing and storageservers and establishing authorized access to the reports via the widearea network, the present invention makes possible the introduction andcontribution of the group of relevant experts even though the group'smembers may be widely or even globally distributed.

Although the invention has been described with reference to thepreferred embodiments illustrated in the drawings, it is noted thatequivalents may be employed and substitutions made herein withoutdeparting from the scope of the invention as recited in the claims. Forexample, referring to an alternate implementation shown in FIG. 8, theimage analysis and recognition process may take place onboard the IRAMunit 112. In the implementation, the IRAM unit 112 includes or hasaccess to the image analysis and recognition software 78 and library 76of reference images previously described as being stored on or accessedby the OATS unit 14. The IRAM unit 112 identifies or attempts toidentify the substance and transmits its results, along with the imageand any other data, to the OATS unit 114, possibly in the form of afinished or preliminary report. Thereafter, this alternateimplementation may function substantially similar to the implementationdescribed above, with the OATS unit 114 uploading the report to the oneor more data processing and storage servers 18 for subsequent access viathe wide area network 16.

1. A remote sensing unit for collecting data for identifying a substance, the remote sensing unit comprising: a position-determining mechanism adapted to determine a geographic location of the remote sensing unit; an imaging device adapted to generate a magnified image of the substance; and a first transmitter adapted to transmit the geographic location and the magnified image.
 2. The remote sensing unit as set forth in claim 1, wherein the position-determining mechanism includes a global positioning system receiver.
 3. The remote sensing unit as set forth in claim 1, wherein the imaging device includes a digital microscope.
 4. The remote sensing unit as set forth in claim 1, wherein the transmitter is adapted to allow for selecting between a wireless manner of communication and a hardwired manner of communication.
 5. The remote sensing unit as set forth in claim 1, further including a sample examination cassette including— a roll of filter paper for receiving the substance; a roll of film providing an impermeable barrier for isolating the substance; and an archive spool for collecting the roll of filter paper and the roll of film.
 6. The remote sensing unit as set forth in claim 1, further including a mass spectrometer adapted to allow for investigating gaseous substances, wherein the mass spectrometer provides an output, with the transmitter being further adapted to transmit the output along with the geographic location and the magnified image.
 7. The remote sensing unit as set forth in claim 1, further including a multiple reagent and sample treatment module adapted to allow for performing micro-chemical and biological testing of the substance, wherein the multiple reagent and sample treatment module provides an output, with the transmitter being further adapted to transmit the output along with the geographic location and the magnified image.
 8. The remote sensing unit as set forth in claim 7, wherein the multiple reagent and sample treatment module is remotely controllable to allow for manually controlling the micro-chemical and biological testing.
 9. The remote sensing unit as set forth in claim 1, further including a control module adapted to allow for remotely controlling operation of the imaging device.
 10. The remote sensing unit as set forth in claim 1, further including a temperature sensor, a wind speed/direction sensor, and a rain sensor that provide an output, with the transmitter being further adapted to transmit the output along with the geographic location and the magnified image.
 11. The remote sensing unit as set forth in claim 1, further including a radiation sensor adapted to measure a background radiation and provide an output, with the transmitter being further adapted to transmit the output along with the geographic location and the magnified image.
 12. The remote sensing unit as set forth in claim 1, further including one or more sensors selected from the group consisting of: GC/MS sensors, acoustic sensors, visual sensors, movement sensors, seismic sensors, magnetic sensors, and solar sensors, wherein each of the sensors is adapted to provide an output, with the transmitter being further adapted to transmit the output along with the geographic location and the magnified image.
 13. The remote sensing unit as set forth in claim 12, further including an open architecture that allows for removing and replacing the one or more sensors without rebooting the remote sensing unit.
 14. The remote sensing unit as set forth in claim 1, wherein the remote sensing unit is adapted to engage in grid computing with one or more other computing resources.
 15. The remote sensing unit as set forth in claim 1, further including a self-righting mechanism adapted to substantially ensure a proper operating orientation of the remote sensing unit.
 16. The remote sensing unit as set forth in claim 15, wherein the self-righting mechanism involves a substantially spherical shape of the remote sensing unit and an offset center of gravity.
 17. The remote sensing unit as set forth in claim 16, wherein the substantially spherical shape is achieved by an inflatable balloon associated with an exterior of the remote sensing unit.
 18. A remote sensing unit for identifying a substance, the system comprising: a position-determining mechanism adapted to determine a geographic location of the remote sensing unit; an imaging device adapted to generate a magnified image of the substance; an image analysis and recognition component adapted to substantially automatically compare the magnified image to a plurality of reference images associated with known substances and thereby attempt to identify the substance based upon similarities between the magnified image of the substance and one or more of the plurality of reference images; and a transmitter adapted to transmit the geographic location, the magnified image, and the identification of the substance by the image analysis and recognition component.
 19. The remote sensing unit as set forth in claim 18, wherein the position determining mechanism includes a global positioning system receiver.
 20. The remote sensing unit as set forth in claim 18, wherein the imaging device includes a digital microscope.
 21. The remote sensing unit as set forth in claim 18, wherein the transmitter is adapted to allow for selecting between a wireless manner of communication and a hardwired manner of communication.
 22. The remote sensing unit as set forth in claim 18, further including a sample examination cassette including— a roll of filter paper for receiving the substance; a roll of film providing an impermeable barrier for isolating the substance; and an archive spool for collecting the roll of filter paper and the roll of film.
 23. The remote sensing unit as set forth in claim 18, further including a mass spectrometer adapted to allow for investigating gaseous substances, wherein the mass spectrometer provides an output, with the transmitter being further adapted to transmit the output along with the geographic location and the magnified image.
 24. The remote sensing unit as set forth in claim 18, further including a multiple reagent and sample treatment module adapted to allow for performing micro-chemical and biological testing of the substance, wherein the multiple reagent and sample treatment module provides an output, with the transmitter being further adapted to transmit the output along with the geographic location and the magnified image.
 25. The remote sensing unit as set forth in claim 24, wherein the multiple reagent and sample treatment module is remotely controllable to allow for manually controlling the micro-chemical and biological testing.
 26. The remote sensing unit as set forth in claim 18, further including a control module adapted to allow for remotely controlling operation of the imaging device.
 27. The remote sensing unit as set forth in claim 18, further including a temperature sensor, a wind speed/direction sensor, and a rain sensor that provide an output, with the transmitter being further adapted to transmit the output along with the geographic location and the magnified image.
 28. The remote sensing unit as set forth in claim 18, further including a radiation sensor adapted to measure a background radiation and provide an output, with the transmitter being further adapted to transmit the output along with the geographic location and the magnified image.
 29. The remote sensing unit as set forth in claim 18, further including one or more sensors selected from the group consisting of: GC/MS sensors, acoustic sensors, visual sensors, movement sensors, seismic sensors, magnetic sensors, solar sensors, wherein each of the sensors is adapted to provide an output, with the transmitter being further adapted to transmit the output along with the geographic location and the magnified image.
 30. The remote sensing unit as set forth in claim 29, further including an open architecture that allows for removing and replacing the one or more sensors without rebooting the remote sensing unit.
 31. The remote sensing unit as set forth in claim 18, wherein the remote sensing unit is adapted to engage in grid computing with one or more other computing resources.
 32. The remote sensing unit as set forth in claim 18, further including a self-righting mechanism adapted to substantially ensure a proper operating orientation of the remote sensing unit.
 33. The remote sensing unit as set forth in claim 32, wherein the self-righting mechanism involves a substantially spherical shape of the remote sensing unit and an offset center of gravity.
 34. The remote sensing unit as set forth in claim 33, wherein the substantially spherical shape is achieved by an inflatable balloon associated with an exterior of the remote sensing unit.
 35. A system for identifying a substance, the system comprising: a remote sensing unit including— a position-determining mechanism adapted to determine a geographic location of the remote sensing unit, an imaging device adapted to generate an image of the substance, and a first transmitter adapted to transmit the geographic location and the image; and a control unit including— a receiver adapted to receive the geographic location and the image transmitted by the remote sensing unit, an image analysis and recognition component adapted to substantially automatically compare the image to a plurality of reference images associated with known substances and thereby attempt to identify the substance based upon similarities between the image of the substance and one or more of the reference images, and one or more second transmitters adapted to transmit a report including the geographic location of the remote sensing unit, the image, and the identification of the substance by the image analysis and recognition component.
 36. The system as set forth in claim 35, wherein the remote sensing unit further includes a multiple reagent and sample treatment module adapted to allow for performing micro-chemical and biological testing of the substance.
 37. The system as set forth in claim 36, wherein the multiple reagent and sample treatment module is remotely controllable by the control unit to allow for manually controlling the micro-chemical and biological testing, wherein the multiple reagent and sample treatment module generates an output that is transmitted to the control unit.
 38. The system as set forth in claim 35, wherein the remote sensing unit further includes a control module adapted to allow for remotely controlling operation of the imaging device from the control unit.
 39. The system as set forth in claim 35, wherein the control unit includes at least two transmitters, including a preferred primary transmitter and a secondary transmitter.
 40. The system as set forth in claim 39, wherein the primary transmitter uses cellular telephone technology.
 41. The system as set forth in claim 39, wherein the secondary transmitter uses satellite-based communication technology.
 42. The system as set forth in claim 35, wherein the control unit is adapted to engage in grid computing with other computing resources to solve complex processing problems.
 43. The system as set forth in claim 35, further comprising one or more remote data processing and storage servers for receiving the report and making the report available to authorized persons via a wide area network.
 44. The system as set forth in claim 43, wherein the one or more data processing and storage servers are provided with evaluation tools for evaluating the report in light of other reports and other relevant data.
 45. The system as set forth in claim 43, wherein the one or more data processing and storage servers are adapted to engage in grid computing with other computing resources.
 46. A system for identifying a substance, the system comprising: a remote sensing unit including— a position-determining mechanism adapted to determine a geographic location of the remote sensing unit, a data collection mechanism adapted to collect data for identifying the substance, and a transmitter adapted to transmit the geographic location and the data collected by the data collection mechanism; and a control unit including— a receiver adapted to receive the geographic location and the data transmitted by the remote sensing unit, a display and user interface adapted to allow an operator of the control unit to view the geographic location and the data, a primary transmitter adapted to allow for communicating a report including the geographic location and the data over a network via a first type of communications link, and a secondary transmitter adapted to allow for communicating the report over the network via a second type of communications link.
 47. The system as set forth in claim 46, wherein the data collection mechanism includes a multiple reagent and sample treatment module adapted to allow for performing micro-chemical and biological testing of the substance.
 48. The system as set forth in claim 47, wherein the multiple reagent and sample treatment module is remotely controllable by the control unit to allow for manually controlling the micro-chemical and biological testing.
 49. The system as set forth in claim 46, wherein the control unit includes at least two transmitters, including a preferred primary transmitter and a secondary transmitter.
 50. The system as set forth in claim 49, wherein the primary transmitter uses cellular telephone technology.
 51. The system as set forth in claim 49, wherein the secondary transmitter uses satellite-based communication technology.
 52. The system as set forth in claim 46, wherein the control unit is adapted to engage in grid computing with other computing resources.
 53. The system as set forth in claim 46, further comprising one or more remote data processing and storage servers for receiving the report and making the report available to authorized persons via a wide area network.
 54. The system as set forth in claim 53, wherein the one or more data processing and storage servers are provided with evaluation tools for evaluating the report in light of other reports and other relevant data.
 55. The system as set forth in claim 53, wherein the one or more data processing and storage servers are adapted to engage in grid computing with other computing resources.
 56. A system for identifying a substance, the system comprising: a remote sensing unit including— a position-determining mechanism adapted to determine a geographic location of the remote sensing unit, an imaging device adapted to generate an image associated with the substance, an image analysis and recognition component adapted to substantially automatically compare the image to a plurality of reference images associated with known substances and thereby attempt to identify the substance based upon similarities between the image of the substance and one or more of the plurality of reference images, and a transmitter adapted to transmit the geographic location, the image, and the identification of the substance by the image analysis and recognition component; and a control unit including— a receiver adapted to receive the geographic location, the image, and the identification of the substance transmitted by the remote sensing unit, a display and user interface adapted to allow an operator of the control unit to view the geographic location, the image, and the identification of the substance, a primary transmitter adapted to allow for communicating a report including the geographic location, the image, and the identification of the substance over a network via a first type of communications link, and a secondary transmitter adapted to allow for communicating the report over the network via a second type of communications link.
 57. The system as set forth in claim 56, wherein the remote sensing unit further includes a multiple reagent and sample treatment module adapted to allow for performing micro-chemical and biological testing of the substance.
 58. The system as set forth in claim 56, wherein the multiple reagent and sample treatment module is remotely controllable by the control unit to allow for manually controlling the micro-chemical and biological testing, wherein the multiple reagent and sample treatment module generates an output that is transmitted to the control unit.
 59. The system as set forth in claim 56, wherein the remote sensing unit further includes a control module adapted to allow for remotely controlling operation of the imaging device from the control unit.
 60. The system as set forth in claim 56, wherein the control unit includes at least two transmitters, including a preferred primary transmitter and a secondary transmitter.
 61. The system as set forth in claim 60, wherein the primary transmitter uses cellular telephone technology.
 62. The system as set forth in claim 60, wherein the secondary transmitter uses satellite-based communication technology.
 63. The system as set forth in claim 56, wherein the control unit is adapted to engage in grid computing with other computing resources.
 64. The system as set forth in claim 56, further comprising one or more remote data processing and storage servers for receiving the report and making the report available to authorized persons via a wide area network.
 65. The system as set forth in claim 64, wherein the one or more data processing and storage servers are provided with evaluation tools for evaluating the report in light of other reports and other relevant data.
 66. The system as set forth in claim 64, wherein the one or more data processing and storage servers are adapted to engage in grid computing with other computing resources. 